用于匹配无人地面车辆的柔性辐条非充气轮胎关键动态性能分析

Kai Chen, Hongxun Fu, Zhen Xiao, Bowen Yang, Shanqian Ni, Ruijian Huo
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引用次数: 0

摘要

为了从根本上提高无人地面车辆及其内部零件的使用寿命,迫切需要解决行驶、转向或转弯时轮胎跳动的问题。本文提出使用柔性辐条非充气轮胎代替充气轮胎。因此,构建了某型充气轮胎和柔性辐条非充气轮胎的三维有限元模型,并验证了模型的有效性。设计了一个模拟方案来研究轮胎的缓冲和横向性能。为了探索软辐条非充气轮胎的结构参数对其缓冲和横向性能的影响程度,开发了基于 L9 (33) 的正交实验仿真方案。结果表明,非充气轮胎在经过颠簸路面产生明显振动后需要 0.006 秒才能恢复稳定,而充气轮胎则需要 0.028 秒。在额定工作条件下,非充气轮胎承受的侧向力为 285.29 N,是充气轮胎 142.59 N 的 1.9 倍。非充气轮胎的缓冲和横向性能受元件角 α 的影响最大,影响程度超过 90%。本文提出的柔性辐条非充气轮胎能有效解决无人地面车辆行驶过程中的轮胎跳动问题,同时为提高非充气轮胎的缓冲和横向性能提供了设计思路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Key dynamic performance analysis of flexible spoke non-pneumatic tire for matched unmanned ground vehicles
To fundamentally improve the lifespan of unmanned ground vehicles and their internal parts, it is urgent to address the problem of tire jumping during driving, steering, or turning. This article proposes the use of flexible spoke non-pneumatic tires instead of pneumatic tires. Therefore, a three-dimensional finite element model of a certain type of pneumatic tire and flexible spoke non-pneumatic tire was constructed and the validity of the model was verified. A simulation scheme was designed to investigate the tire cushioning and lateral performance. In order to explore the degree of influence of the structural parameters of the flexible spoke non-pneumatic tire on its cushioning and lateral performance, an orthogonal experimental simulation scheme based on L9 (33) was developed. The results show that the non-pneumatic tire requires 0.006 s to recover stability after experiencing significant vibration due to passing over a bump, while the pneumatic tire requires 0.028 s. Under rated working conditions, the non-pneumatic tire is subjected to a lateral force of 285.29 N, which is 1.9 times that of the pneumatic tire’s 142.59 N. The cushioning and lateral performance of the non-pneumatic tire is most affected by the element angle α, with an impact level of over 90%. The flexible spoke non-pneumatic tire proposed in this article can effectively solve the tire jumping problem of unmanned ground vehicles during driving, while providing design ideas for improving the cushioning and lateral performance of non-pneumatic tires.
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